A serum folate assay wherein the serum folate is stabilized with dimercaptosuccinic acid or thioctic acid.
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11. A serum folate standard reagent kit for use in standardization of an assay for serum folate, said standard reagent kit comprising
in an appropriate container, a measured portion of folate, and in an appropriate container, a serum folate stabilizer selected from the group consisting of dimercaptosuccinic acid and thioctic acid.
12. A serum folate control reagent kit for use in providing a control in an assay for serum folate, said control reagent kit comprising
in an appropriate container, a measured portion of a serum containing serum folate, and in an appropriate container, a serum folate stabilizer selected from the group consisting of dimercaptosuccinic acid and thioctic acid.
1. In a kit useful in assaying for the presence of serum folate in a sample, said kit including
in an appropriate container, a serum folate tracer material capable of being combined with said sample, in an appropriate container, a serum folate stabilizer capable of being combined with said sample, said kit being adapted to utilize a chemical or heat treatment means for inactivating endogenous serum folate binding protein in an inactivation reaction, a means for chemically binding a portion of said serum folate and serum folate tracer, and the improvement comprising said serum folate stabilizer being selected from the group consisting of dimercaptosuccinic acid and thioctic acid.
6. In a method for assaying for the presence of serum folate in a sample, said method including the steps of
performing an inactivation reaction on said sample to inactivate endogenous serum folate binding protein, wherein a serum folate stabilizer is present during the inactivation reaction, combining a measured amount of the sample with a measured amount of serum folate tracer material to form a combined serum folate material, binding a portion of the combined measured sample and measured serum folate tracer material to a specific binder for serum folate, separating the bound portion of the combined serum folate and serum folate tracer material from the unbound portion of the combined serum folate and serum folate tracer material, and measuring the presence of serum folate tracer in at least one of the bound or unbound portions of the combined serum folate and serum folate tracer material,
the improvement comprising using a serum folate stabilizer in the combined serum folate material selected from the group consisting of dimercaptosuccinic acid and thioctic acid. 2. The kit of
3. The kit of
4. The kit of
5. The kit of
7. The method of
8. The method of
9. The method of
10. The method of
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This application is a continuation of application Ser. No. 591,147, filed Mar. 19, 1984, now abandoned.
This invention relates to the assay of serum folate. It particularly relates to improved stabilizers for use in the assay.
Folate is a generic term for many naturally occurring pteroylglutamic acid analogs. These analogs are hydrolyzed before entering the blood stream. The hydrolysis appears to be mediated by the conjugate enzyme, gammaglutamyl carboxpeptidase. The metabolite, N5 -Methyltetrahydrofolate (N5 MTHF), is the major circulatory and storage form of folic acid, which is ultimately oxidized to the physiologically active formyl derivative.
The folates play a significant role in the synthesis of purines and thymine required for DNA synthesis and participate in a variety of reactions as coenzymes for single carbon moieties transfer. Humans rely completely on diet for their folate requirements. Since body folate stores are not large, folate deficiency can develop rapidly. Measurement of either serum or red cell folate levels provides useful diagnostic information for determining various types of nutritional anemias. A low serum or red cell folate level is a strong indication that the patient has folate deficiency. In addition, measurement of folate is useful for monitoring a patient's response to therapy.
Recent advances in radioassay technology have resulted in the development of folate radioassays. These methods are less time consuming and more reproducible than microbiological assays and are not subject to interference by antibiotics or antimetabolites.
The folate assay described in this invention utilizes a treated tube procedure which allows a rapid and complete separation of bound from free radioactively labeled antigen. Polypropylene assay tubes are treated with specific folate binding protein. During the assay, radioiodinated folate and endogenous folate from a patient sample are incubated in the treated tube. After the incubation period is completed, the bound folate is separated from free folate by aspiration and washing of the assay tube. The amount of folate bound in the assay tube is compared with values obtained from known folate standards. The folate concentration in the patient sample can then be calculated.
Other folate assay procedures based on competitive binding techniques are known. See for example, U.S. Pat. No. 4,028,465 which discloses the use of dithiopolyols.
In accordance with the present invention, there is disclosed an assay for serum folate employing the competitive binding technique in which endogenous serum folate binding proteins are inactivated by heat or alkaline treatment before the competitive binding step in the presence of a buffered solution containing a stabilizer wherein the improvement comprises employing as a stabilizer a compound selected from dimercaptosuccinic acid (DMSA) or thioctic acid.
The amount of stabilizer employed should be from about 0.05% on a weight-to-reaction volume basis to about 0.5% on a weight-to-reaction volume basis. A preferred concentration is in the range of from 0.1 to 0.3% on a weight-to-reaction volume basis.
These stabilizers have an advantage over previously disclosed stabilizers in that they are more effective and have a longer shelf life than the previous stabilizers.
The stabilizers of this invention can be employed with either manual assays or automated assays.
The following is a description of the reagents and materials employed in the assay kit, and flow diagrams and descriptions of the use of the kit in both an automated and a manual assay.
| ______________________________________ |
| Folate Assay Tubes 200 |
| Assay tubes treated with specific folate binding |
| protein. Store at 4°C |
| Folate 125 I Tracer Solution |
| 1 vial |
| 125 I labeled folate is supplied lyophilized in |
| borate-BSA buffer. Store at 4°C |
| Folate Denaturing Buffer Solution |
| 1 bottle |
| Contains 95 ml of borate phosphate buffer and 0.01% |
| sodium azide. Store at 4°C |
| Folate Assay Buffer Solution |
| 1 bottle |
| Contains 0.1 M borate and 0.01% sodium azide. |
| Store at 4°C |
| Folate Standards 6 vials |
| Six concentrations of folate standards (0, 1.0, 2.5, |
| 5.0, 10.0 and 20.0 ng/ml) are supplied lyophilized |
| in protein based borate buffer. Unreconstituted |
| standards should be stored at 4°C |
| Folate Control Serum I 1 vial |
| Folate Control Serum II 1 vial |
| Two control sera are supplied lyophilzed in |
| defibrinated human plasma. Values are given on the |
| vial labels. Unreconstituted control sera should be |
| stored at 4°C |
| Folate Stabilizing Solution 1 vial |
| Contains 5 ml of 5% aqueous solution of 2,3 dimer- |
| captosuccinic acid. Keep vial tightly stopped. |
| ______________________________________ |
Prepare master Denaturing Buffer solution by mixing 1 vial of Folate Stabilizing Solution and 1 bottle of Folate Denaturing Buffer Solution. Keep bottle tightly capped.
Folate Tracer Solution and Folate Assay Buffer Solution must be combined before use. Pour the folate tracer solution directly into a clean 500 ml Erlenmeyer flask or amber glass dispenser bottle. Wash out the tracer solution vial three times with the assay buffer solution, adding these washes to the flask or bottle. Add remaining assay buffer solution and mix thoroughly. Place diluted folate tracer solution label provided in the securetainer on the flask or bottle to identify lot number and expiration date of the contents. Insure that sufficient diluted tracer solution is in the dispenser for the present assay. At the end of the assay, store excess diluted tracer solution at 4°C in an amber bottle or Erlenmeyer flask.
All of the components must be at room temperature before beginning an assay.
The reagents are stable for a minimum of eight weeks when stored at 4°C in a dry, dark area. Prolonged exposure to light or heat should be avoided. All reagents should be discarded at their expiration date.
The stability of reconstituted components depends greatly upon the purity of distilled water used and upon the cleanliness of glassware.
PAC GeneraalBefore proceeding with assays, bring all reagents and assay tubes to room temperature. All determinations should be performed in duplicate. A standard curve must be performed with each series of unknowns.
PAC Denaturation of Standards, Control Sera, and Patient SamplesAdd 250 ul of standard, control or patient sample and 750 ul of Master Folate Denaturing Buffer Solution to a glass minisample tube. Gently vortex. Place minisample tubes into either a heat block with holes for 8×50 mm tubes or a water bath adjusted to 90°-95°C for 20 minutes. Cool to room temperature before use. Then proceed to next step.
1. For duplicate mode of operation, prepare sample tubes as follows:
| ______________________________________ |
| Sample Tube Number |
| Vial Contents |
| ______________________________________ |
| 1 1 Standard: 0 ng/ml |
| 2 2 Standard: 1.0 ng/ml |
| 3 3 Standard: 2.5 ng/ml |
| 4 4 Standard: 5.0 ng/ml |
| 5 5 Standard: 10 ng/ml |
| 6 6 Standard: 20 ng/ml |
| 7 CI Control Serum, I |
| 8 CII Control Serum, II |
| 9 Control Serum |
| 10-100 Patient Samples |
| ______________________________________ |
2. Check that the water reservoirs are full, the waste containers are empty, and the rinse pumps are primed.
3. Set pipette volumes as follows:
| ______________________________________ |
| Pump Name Volume Size Setting |
| ______________________________________ |
| Reagent 600 ul 1 ml 60% |
| Sample 400 ul 1 ml 40% |
| Sample Air 15 ul 50 ul 30% |
| Excess 30 ul 200 ul 15% |
| Rinse 1.42 5 ml 28.5% |
| Rinse 1.42 5 ml 28.5% |
| ______________________________________ |
4. Clear the reagent transfer tip.
5. Install a tracer dispenser, cycle tip down, prime with 0.75 ml of reagent, cycle tip up and let stand for 5 minutes. Cycle tip down again and prime with an additional 0.5 ml of reagent. Cycle tip to home position.
6. Load Assay racks.
7. Load Sample racks. (If water bath is used for denaturation, be sure the outside of sample tubes are dry before transferring to dry rack).
8. Verify that the ratio of Sample Racks to Assay Racks is appropriate.
9. Set incubation time to 90.0 minutes.
10. Check that incubation temperature is 37°C
11. Count radiactivity for recommended time.
12. Report results.
PAC MANUAL ASSAY PROCEDUREAssay
1. Label an appropriate number of folate assay tubes according to the following general outline.
| ______________________________________ |
| Sample Tube |
| Assay Tube |
| Vial Contents |
| ______________________________________ |
| 1 1,2 1 Standard: 0 ng/ml |
| 2 3,4 2 Standard: 1.0 ng/ml |
| 3 5,6 3 Standard: 2.5 ng/ml |
| 4 7,8 4 Standard: 5.0 ng/ml |
| 5 9,10 5 Standard: 10 ng/ml |
| 6 11,12 6 Standard: 20 ng/ml |
| 7 13,14 CI Control I |
| 8 15,16 CII Control II |
| 9 17,18 Control Serum |
| 10-100 19-200 Patient Samples |
| ______________________________________ |
2. Transfer 400 ul of the denatured standards, controls and patient samples to the appropriate assay tubes.
3. Add 600 ul of diluted tracer to all assay tubes. Gently vortex.
4. Incubate at 37°C for 90 minutes.
5. Aspirate liquid from each assay tube. (Note: Be sure that aspirating tip touches the bottom of the assay tube to remove all of the liquid. Avoid scraping inside walls. Use a suitable water aspirator with an Erlenmeyer flask to trap the tube contents.)
6. Wash with 1.3 to 1.5 ml of distilled water twice, aspirating after each wash.
7. Count radiactivity in the tubes on a gamma counter set for the detection of I125. Assay tubes may need to be placed in larger tubes compatible with the gamma counter.
The following examples illustrate this invention; however, those skilled in the art realize that many changes and modifications can be made without exceeding the scope of this invention.
N5 MTHF is spiked into the following protein bases; normal human serum pool, pregnant female serum pool and stripped human serum pool. The average recovery follows:
| ______________________________________ |
| ng/ml No. of Added N5 MTHF |
| % added |
| added Determinations |
| Recovered ± 1SD* |
| Recovery |
| ______________________________________ |
| +5 6 5.73 ± 0.77 114.57 |
| +10 6 10.65 ± 0.88 106.48 |
| +15 6 14.45 ± 2.08 96.34 |
| ______________________________________ |
Folic acid is spiked into the normal human serum pools. The average recovery follows:
| ______________________________________ |
| Folic acid |
| No. of Added folic acid |
| % added |
| (ng/ml) Determinations |
| Recovered ± 1SD |
| Recovery |
| ______________________________________ |
| +4 6 4.62 ± 0.58 |
| 110.2 |
| +8 6 8.77 ± 0.45 |
| 107.0 |
| +16 6 15.92 ± 0.32 |
| 98.2 |
| ______________________________________ |
Precision data was generated for a low, medium and high folate human serum pool. Five (5) assays using ten (10) samples per pool per assay were tested. Results were calculated by Rodbard calculations.
| ______________________________________ |
| Low Medium High |
| pool pool pool |
| ______________________________________ |
| Mean 2.26 7.00 15.93 |
| (ng/ml) |
| Intra assay 4.75% 4.07% 3.08% |
| coefficient |
| variation (CV) |
| Inter Assay CV |
| 5.81% 5.44% 6.05% |
| ______________________________________ |
Similar data was obtained by replacing DMSA with dl thioctic Acid.
0.5% DMSA (weight to volume) was added to the protein based folic acid standards and controls. The stability array results show that the DMSA added standard and controls are stable after 10 weeks storage at 4° C.±2°C in liquid form.
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| Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
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| Nov 08 1989 | ICN MICROMEDIC SYSTEMS, INC | FIRST CITY, , A NATIONAL BANKING ASSOCIATION | SECURITY INTEREST SEE DOCUMENT FOR DETAILS | 005194 | /0966 | |
| Nov 30 1990 | ICN MICROMEDIC SYSTEMS, INC , A CORP OF CA | FIRST CITY, | SECURITY INTEREST SEE DOCUMENT FOR DETAILS | 005529 | /0609 |
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